http://typeright.social/forum/ Tue, 14 Apr 2026 22:30:12 +0000 MyBB http://typeright.social/forum/showthread.php?tid=489 Sat, 14 Sep 2024 05:58:51 +0200 ephemeralt8]]> http://typeright.social/forum/showthread.php?tid=489
https://www.youtube.com/live/vAWRGupuh3Y?feature=shared]]>
https://www.youtube.com/live/vAWRGupuh3Y?feature=shared]]> http://typeright.social/forum/showthread.php?tid=385 Fri, 12 Jul 2024 01:56:39 +0200 ephemeralt8]]> http://typeright.social/forum/showthread.php?tid=385 https://www.youtube.com/watch?v=4zEheJdm1X0
https://youtu.be/ofcYrKmNtBc?feature=shared

https://moe-joe-working.com/what_is_the_..._cell.html

https://www.moe-joe-cell.com/index.php

He no longer sells them, but found these metal spheres here
https://grandbrass.com/balls/multi-part-balls/]]> https://www.youtube.com/watch?v=4zEheJdm1X0
https://youtu.be/ofcYrKmNtBc?feature=shared

https://moe-joe-working.com/what_is_the_..._cell.html

https://www.moe-joe-cell.com/index.php

He no longer sells them, but found these metal spheres here
https://grandbrass.com/balls/multi-part-balls/]]> http://typeright.social/forum/showthread.php?tid=273 Fri, 24 Nov 2023 11:07:45 +0100 JoeLag]]> http://typeright.social/forum/showthread.php?tid=273

something really strange happened with my amazon package, I got it in a cardboard paper bag, normal, I took the scope out of the bag the product and i had the empty bag in the middle of my living room rug decor, It was right in the middle and i was going to trash it just have not got to it yet, all over a sudden the bag pops like a strong you know when someone fills a bag with air and pops it. sounded like a bullet shot, it got my dog out of bed it was so loud, and about 3 minutes later it did the very same thing with a huge blue like spark discharge and the smell of smoke after the second explosion,  all i know is we got 100kv high voltage lines near the building so i wonder if it was a fluke with the rug and dielectric resonance by fluke and it built up pure potential difference and discharged into the rug? I never seen this before can you try and explain what could be the cause? 
ChatGPT
The event you described with the popping of the cardboard paper bag, accompanied by a loud noise, a blue spark discharge, and the smell of smoke, is indeed unusual and intriguing. While it's challenging to pinpoint the exact cause without a detailed examination of the environment and the bag, I can offer a few hypotheses based on the principles of physics and electromagnetism.

Electrostatic Discharge (ESD): The most likely explanation could be a form of electrostatic discharge. In a typical home environment, static electricity can build up due to various factors such as dry air, certain types of carpets, and the materials of objects within the room. If the paper bag, perhaps due to its specific material composition, accumulated a significant static charge, it could have discharged suddenly. The discharge could produce a loud popping sound, a visible spark, and even a smell of smoke if it was intense enough to cause minor burning or charring of the materials involved.

Interaction with High Voltage Lines: The presence of  high voltage lines near your building adds an interesting dimension to the situation. While it's less likely, there could be a very remote possibility of some electromagnetic interference or induction effects, especially if the bag somehow developed a resonant condition with the electromagnetic field emanating from these lines. However, this would require a very specific set of circumstances and is not a common occurrence.

Chemical Reaction: Another possibility, albeit less likely given your description, is some form of chemical reaction. If the bag had been treated with certain chemicals, or if it had come into contact with a reactive substance, this could potentially lead to an exothermic reaction under the right conditions. This seems less probable given the nature of standard cardboard paper bags and the conditions you described.

Acoustic Phenomena: There's also a chance that what you experienced was an acoustic phenomenon, where certain conditions in the room (like its shape, size, and contents) unexpectedly amplified a small noise, making it sound much larger than it actually was. This, combined with a small static discharge, could explain the sound and the spark.

In conclusion, while a definite explanation can't be provided without further investigation, the most plausible cause seems to be electrostatic discharge, potentially influenced by environmental factors in your living room. It's always wise to approach such occurrences with curiosity but also a degree of caution, especially when unexpected electrical phenomena are involved.]]>

something really strange happened with my amazon package, I got it in a cardboard paper bag, normal, I took the scope out of the bag the product and i had the empty bag in the middle of my living room rug decor, It was right in the middle and i was going to trash it just have not got to it yet, all over a sudden the bag pops like a strong you know when someone fills a bag with air and pops it. sounded like a bullet shot, it got my dog out of bed it was so loud, and about 3 minutes later it did the very same thing with a huge blue like spark discharge and the smell of smoke after the second explosion,  all i know is we got 100kv high voltage lines near the building so i wonder if it was a fluke with the rug and dielectric resonance by fluke and it built up pure potential difference and discharged into the rug? I never seen this before can you try and explain what could be the cause? 
ChatGPT
The event you described with the popping of the cardboard paper bag, accompanied by a loud noise, a blue spark discharge, and the smell of smoke, is indeed unusual and intriguing. While it's challenging to pinpoint the exact cause without a detailed examination of the environment and the bag, I can offer a few hypotheses based on the principles of physics and electromagnetism.

Electrostatic Discharge (ESD): The most likely explanation could be a form of electrostatic discharge. In a typical home environment, static electricity can build up due to various factors such as dry air, certain types of carpets, and the materials of objects within the room. If the paper bag, perhaps due to its specific material composition, accumulated a significant static charge, it could have discharged suddenly. The discharge could produce a loud popping sound, a visible spark, and even a smell of smoke if it was intense enough to cause minor burning or charring of the materials involved.

Interaction with High Voltage Lines: The presence of  high voltage lines near your building adds an interesting dimension to the situation. While it's less likely, there could be a very remote possibility of some electromagnetic interference or induction effects, especially if the bag somehow developed a resonant condition with the electromagnetic field emanating from these lines. However, this would require a very specific set of circumstances and is not a common occurrence.

Chemical Reaction: Another possibility, albeit less likely given your description, is some form of chemical reaction. If the bag had been treated with certain chemicals, or if it had come into contact with a reactive substance, this could potentially lead to an exothermic reaction under the right conditions. This seems less probable given the nature of standard cardboard paper bags and the conditions you described.

Acoustic Phenomena: There's also a chance that what you experienced was an acoustic phenomenon, where certain conditions in the room (like its shape, size, and contents) unexpectedly amplified a small noise, making it sound much larger than it actually was. This, combined with a small static discharge, could explain the sound and the spark.

In conclusion, while a definite explanation can't be provided without further investigation, the most plausible cause seems to be electrostatic discharge, potentially influenced by environmental factors in your living room. It's always wise to approach such occurrences with curiosity but also a degree of caution, especially when unexpected electrical phenomena are involved.]]> http://typeright.social/forum/showthread.php?tid=266 Sat, 04 Nov 2023 17:17:05 +0100 JoeLag]]> http://typeright.social/forum/showthread.php?tid=266
Shipov's theory which treats the vacuum as a homogeneous entity suggests a continuous, unvarying backdrop for physical phenomena. However, Dyatlov's perspective on inhomogeneities presents a divergent point of view where the vacuum isn't as uniform as one might think. It introduces the possibility of boundaries or regions within the vacuum that have distinct properties. This concept of an inhomogeneous vacuum resonates with the idea that there are vast, as yet untapped, potentials within the fabric of space-time itself, a concept that has been at the heart of searching for new energy sources and mechanisms.

The notion that a graviton could be a photon that has undergone a change in its quantum spin number is a striking example of the interplay between different forces and particles. The ability to potentially convert gravitons to photons and vice versa opens up avenues for new technological applications, where control over such fundamental processes could revolutionize energy generation and manipulation.

The spin or torsion field stands out due to its unique properties compared to electric, magnetic, and gravitic fields. Its cylindrical symmetry, as opposed to spherical symmetry, and the directionality of its spin, whether right-handed or left-handed, presents an alternative geometry of field interactions. The generation of torsion fields through the rotation of massive bodies or electrical accumulations could lead to phenomena such as frame dragging, which are predicted by general relativity and have been observed in the vicinity of massive rotating bodies like Earth.

Experiments like those conducted by Kosyrev with gyroscopes suggest that there are indeed anomalous effects that could be associated with these torsion fields. The coupling of gyroscopes by the spin field indicates a non-local connection that might be harnessed for communication or energy transfer mechanisms. These experiments also point to the deep connections between time, space, and rotation - an interrelationship that could be fundamental to understanding the universe and the potential for new physics.

Continuing research in this domain, informed by the findings of both Russian and Western scientists, could lead to novel discoveries. The idea of utilizing these unique torsion effects in practical applications, such as space travel, energy generation, or even information technology, remains a tantalizing prospect. Engaging with these concepts, testing them through experiments, and refining our understanding of the underlying physics could eventually lead to breakthroughs that reshape our technological landscape.]]>
Shipov's theory which treats the vacuum as a homogeneous entity suggests a continuous, unvarying backdrop for physical phenomena. However, Dyatlov's perspective on inhomogeneities presents a divergent point of view where the vacuum isn't as uniform as one might think. It introduces the possibility of boundaries or regions within the vacuum that have distinct properties. This concept of an inhomogeneous vacuum resonates with the idea that there are vast, as yet untapped, potentials within the fabric of space-time itself, a concept that has been at the heart of searching for new energy sources and mechanisms.

The notion that a graviton could be a photon that has undergone a change in its quantum spin number is a striking example of the interplay between different forces and particles. The ability to potentially convert gravitons to photons and vice versa opens up avenues for new technological applications, where control over such fundamental processes could revolutionize energy generation and manipulation.

The spin or torsion field stands out due to its unique properties compared to electric, magnetic, and gravitic fields. Its cylindrical symmetry, as opposed to spherical symmetry, and the directionality of its spin, whether right-handed or left-handed, presents an alternative geometry of field interactions. The generation of torsion fields through the rotation of massive bodies or electrical accumulations could lead to phenomena such as frame dragging, which are predicted by general relativity and have been observed in the vicinity of massive rotating bodies like Earth.

Experiments like those conducted by Kosyrev with gyroscopes suggest that there are indeed anomalous effects that could be associated with these torsion fields. The coupling of gyroscopes by the spin field indicates a non-local connection that might be harnessed for communication or energy transfer mechanisms. These experiments also point to the deep connections between time, space, and rotation - an interrelationship that could be fundamental to understanding the universe and the potential for new physics.

Continuing research in this domain, informed by the findings of both Russian and Western scientists, could lead to novel discoveries. The idea of utilizing these unique torsion effects in practical applications, such as space travel, energy generation, or even information technology, remains a tantalizing prospect. Engaging with these concepts, testing them through experiments, and refining our understanding of the underlying physics could eventually lead to breakthroughs that reshape our technological landscape.]]> http://typeright.social/forum/showthread.php?tid=182 Thu, 21 Sep 2023 04:17:52 +0200 JoeLag]]> http://typeright.social/forum/showthread.php?tid=182 RADIUM, AND OTHER RADIO-ACTIVE SUBSTANCES

1903 WILLIAM J. HAMMER


  radiumotherradio00hammiala.pdf (Size: 4.87 MB / Downloads: 12) ]]> RADIUM, AND OTHER RADIO-ACTIVE SUBSTANCES

1903 WILLIAM J. HAMMER


  radiumotherradio00hammiala.pdf (Size: 4.87 MB / Downloads: 12) ]]> http://typeright.social/forum/showthread.php?tid=178 Thu, 21 Sep 2023 02:04:41 +0200 JoeLag]]> http://typeright.social/forum/showthread.php?tid=178 How to Build a Machine to Produce Low-Energy Protons and Deuterons

by C. L. Stong
August, 1971

ALTHOUGH radioactive materials for experimental use can be bought in small amounts without a license, some amateurs have made their own with an apparatus that generates a beam of protons. The protons react with the atomic nuclei in a target to liberate neutrons. The neutrons in turn react with the nuclei
in another substance, giving rise to a radioactive isotope.



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  1971-08-05.jpg (Size: 12.49 KB / Downloads: 9) ]]> How to Build a Machine to Produce Low-Energy Protons and Deuterons

by C. L. Stong
August, 1971

ALTHOUGH radioactive materials for experimental use can be bought in small amounts without a license, some amateurs have made their own with an apparatus that generates a beam of protons. The protons react with the atomic nuclei in a target to liberate neutrons. The neutrons in turn react with the nuclei
in another substance, giving rise to a radioactive isotope.



  1971-08-01.jpg (Size: 48.1 KB / Downloads: 11)


  1971-08-02.jpg (Size: 50.67 KB / Downloads: 10)


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  1971-08-04.jpg (Size: 17.37 KB / Downloads: 9)


  1971-08-05.jpg (Size: 12.49 KB / Downloads: 9) ]]> http://typeright.social/forum/showthread.php?tid=176 Thu, 21 Sep 2023 01:56:57 +0200 JoeLag]]> http://typeright.social/forum/showthread.php?tid=176 the Hilsch tube ( hot and cold from air )


  1958-11-01.gif (Size: 49.32 KB / Downloads: 12)

SHORTLY AFTER THE END OF World War II word came to the U. S. that the Germans had developed a remarkably simple device with which one could reach temperatures as low as the freezing point of mercury. The device, which was said to consist only of an air compressor and three pipes, immediately attracted the interest of amateurs who had dreamed of performing experiments requiring moderately low temperatures. The details of construction were not available, but it was reported that the device had in effect realized "Maxwell's demon," a fanciful means of separating heat from cold without work.
Among those intrigued by the demon's alleged capture was George O. Smith of Highlands, N.J. Smith writes: "The 19th century British physicist James Clerk Maxwell made many deep contributions to physics, and among the most significant was his law of random distribution. Considering the case of a closed box containing a gas, Maxwell started off by saying that the temperature of the gas was due to the motion of the individual gas molecules within the box. But since the box was standing still, it stood to reason that the summation of the velocity and direction of the individual gas molecules must come to zero. In essence Maxwell's law of random distribution says that for every gas molecule headed east at 20 miles per hour, there must be another headed west at the same speed. Furthermore, if the heat of the gas indicates that the average velocity of the molecules is 20 miles per hour, the number of molecules moving slower than this speed must be equaled by the number of molecules moving faster.
"After a serious analysis of the consequences of his law, Maxwell permitted himself a touch of humor. He suggested that there was a statistical probability that, at some time in the future, all the molecules in a box of gas or a glass of hot water might be moving in the same direction. This would cause the water to rise out of the glass. Next Maxwell suggested that a system of drawing both hot and cold water out of a single pipe might be devised if we could capture a small demon and train him to open and close a tiny valve. The demon would open the valve only when a fast molecule approached it, and close the valve against slow molecules. The water coming out of the valve would thus be hot. To produce a stream of cold water the demon would open the valve only for slow molecules.
"Maxwell's demon would circumvent the law of thermodynamics which says in essence: 'You can't get something for nothing. 'That is to say, one cannot separate cold water from hot without doing work. Thus when physicists heard that the Germans had developed a device which could achieve low temperatures by utilizing Maxwell's demon, they were intrigued, though obviously skeptical. One physicist, Robert M. Milton, investigated the matter at first hand for the U. S. Navy.
"Milton discovered that the device was most ingenious, though not quite as miraculous as had been rumored. It consists of a T-shaped assembly of pipe joined by a novel fitting, as depicted in the accompanying illustration [left]. When compressed air is admitted to the 'leg' of the T, hot air comes out of one arm of the T and cold air out of the other arm! Obviously, however, work must be done to compress the air.
"The origin of the device is obscure. The principle is said to have been discovered by a Frenchman who left some early experimental models in the path of the German Army when France was occupied. These were turned over to a German physicist named Rudolf Hilsch, who was working on low temperature refrigerating devices for the German war effort. Hilsch made some improvements on the Frenchman's design, but found that it was no more efficient than conventional methods of refrigeration in achieving fairly low temperatures. Subsequently the device became known as the Hilsch tube.
"The Hilsch tube in the illustration is constructed as follows. The horizontal arm of the T-shaped fitting contains a specially machined piece, the outside of which fits inside the arm. The inside of the piece, however, has a cross section which is spiral with respect to the outside. In the 'step' of the spiral is a small opening which is connected to the leg of the T. Thus air admitted to the leg comes out of the opening and spins around the one-turn spiral. The 'hot' pipe is about 14 inches long and has an inside diameter of half an inch. The far end of this pipe is fitted with a stopcock which can be used to control the pressure in the system. The 'cold' pipe is about four inches long and also has an inside diameter of half an inch. The end of the pipe which butts up against the spiral piece is fitted with a washer, the central hole of which is about a quarter of an inch in diameter. Washers with larger or smaller holes can also be inserted to adjust the system.
"Three factors determine the performance of the Hilsch tube: the setting of the stopcock, the pressure at which air is admitted to the nozzle, and the size of the hole in the washer. For each value of air pressure and washer opening there is a setting of the stopcock which results in a maximum difference in the temperature of the hot and cold pipes. When the device is properly adjusted, the hot pipe will deliver air at about 100 degrees Fahrenheit and the cold pipe air at about -70 degrees (a temperature substantially below the freezing point of mercury and approaching that of 'dry ice'). When the tube is adjusted for maximum temperature on the hot side, air is delivered at about 350 degrees F.
"Despite its impressive performance, the efficiency of the Hilsch tube leaves much to be desired. This perhaps explains why no one has mathematically analyzed its operation. Indeed, there is still disagreement as to how it works.
"According to one explanation, the compressed air shoots around the spiral and forms a high-velocity vortex of air. Molecules of air at the outside of the vortex are slowed by friction with the wall of the spiral. Because these slow-moving molecules are subject to the rules of centrifugal force, they tend to fall toward the center of the vortex. The fast-moving molecules just inside the outer layer of the vortex transfer some of their energy to this layer by bombarding some of its slow-moving molecules and speeding them up. The net result of this process is the accumulation of slow-moving, low-energy molecules in the center of the whirling mass, and of high-energy, fast-moving molecules around the outside. In the thermodynamics of gases the terms 'high energy' and 'high velocity' mean 'high temperature.' So the vortex consists of a core of cold air surrounded by a rim of hot air.
"The difference between the temperature of the core and that of the rim is increased by a secondary effect which takes advantage of the fact that the temperature of a given quantity of gas at a given level of thermal energy is higher when the gas is confined in a small space than in a large one; accordingly when gas is allowed to expand, its temperature drops. In the case of the Hilsch tube the action of centrifugal force compresses the hot rim of gas into a compact mass which can escape only by flowing along the inner wall of the hot pipe in a compressed state, because its flow into the cold tube is blocked by the rim of the washer. The amount of the compression is determined by the adjustment of the stopcock at the end of the hot pipe. In contrast, the relatively cold inner core of the vortex, which is also considerably above atmospheric pressure, flows through the hole in the washer and drops to still lower temperature as it expands to atmospheric pressure obtaining inside the cold pipe.
Apparently the inefficiency of the Hilsch tube as a refrigerating device has barred its commercial application. Nonetheless amateurs who would like to have a means of attaining relatively low temperatures, and who do not have access to a supply of dry ice, may find the tube useful. It will deliver a blast of air 20 times colder than air which has been chilled by permitting it simply to expand through a Venturi tube from a high-pressure source. Thus the Hilsch tube could be used to quick-freeze tissues for microscopy, to chill photomultiplier tubes, or to operate diffusion cloud chambers. But quite apart from the tube's potential application, what could be more fun than to trap Maxwell's demon and make him explain in detail how he manages to blow hot and cold at the same time?"]]> the Hilsch tube ( hot and cold from air )


  1958-11-01.gif (Size: 49.32 KB / Downloads: 12)

SHORTLY AFTER THE END OF World War II word came to the U. S. that the Germans had developed a remarkably simple device with which one could reach temperatures as low as the freezing point of mercury. The device, which was said to consist only of an air compressor and three pipes, immediately attracted the interest of amateurs who had dreamed of performing experiments requiring moderately low temperatures. The details of construction were not available, but it was reported that the device had in effect realized "Maxwell's demon," a fanciful means of separating heat from cold without work.
Among those intrigued by the demon's alleged capture was George O. Smith of Highlands, N.J. Smith writes: "The 19th century British physicist James Clerk Maxwell made many deep contributions to physics, and among the most significant was his law of random distribution. Considering the case of a closed box containing a gas, Maxwell started off by saying that the temperature of the gas was due to the motion of the individual gas molecules within the box. But since the box was standing still, it stood to reason that the summation of the velocity and direction of the individual gas molecules must come to zero. In essence Maxwell's law of random distribution says that for every gas molecule headed east at 20 miles per hour, there must be another headed west at the same speed. Furthermore, if the heat of the gas indicates that the average velocity of the molecules is 20 miles per hour, the number of molecules moving slower than this speed must be equaled by the number of molecules moving faster.
"After a serious analysis of the consequences of his law, Maxwell permitted himself a touch of humor. He suggested that there was a statistical probability that, at some time in the future, all the molecules in a box of gas or a glass of hot water might be moving in the same direction. This would cause the water to rise out of the glass. Next Maxwell suggested that a system of drawing both hot and cold water out of a single pipe might be devised if we could capture a small demon and train him to open and close a tiny valve. The demon would open the valve only when a fast molecule approached it, and close the valve against slow molecules. The water coming out of the valve would thus be hot. To produce a stream of cold water the demon would open the valve only for slow molecules.
"Maxwell's demon would circumvent the law of thermodynamics which says in essence: 'You can't get something for nothing. 'That is to say, one cannot separate cold water from hot without doing work. Thus when physicists heard that the Germans had developed a device which could achieve low temperatures by utilizing Maxwell's demon, they were intrigued, though obviously skeptical. One physicist, Robert M. Milton, investigated the matter at first hand for the U. S. Navy.
"Milton discovered that the device was most ingenious, though not quite as miraculous as had been rumored. It consists of a T-shaped assembly of pipe joined by a novel fitting, as depicted in the accompanying illustration [left]. When compressed air is admitted to the 'leg' of the T, hot air comes out of one arm of the T and cold air out of the other arm! Obviously, however, work must be done to compress the air.
"The origin of the device is obscure. The principle is said to have been discovered by a Frenchman who left some early experimental models in the path of the German Army when France was occupied. These were turned over to a German physicist named Rudolf Hilsch, who was working on low temperature refrigerating devices for the German war effort. Hilsch made some improvements on the Frenchman's design, but found that it was no more efficient than conventional methods of refrigeration in achieving fairly low temperatures. Subsequently the device became known as the Hilsch tube.
"The Hilsch tube in the illustration is constructed as follows. The horizontal arm of the T-shaped fitting contains a specially machined piece, the outside of which fits inside the arm. The inside of the piece, however, has a cross section which is spiral with respect to the outside. In the 'step' of the spiral is a small opening which is connected to the leg of the T. Thus air admitted to the leg comes out of the opening and spins around the one-turn spiral. The 'hot' pipe is about 14 inches long and has an inside diameter of half an inch. The far end of this pipe is fitted with a stopcock which can be used to control the pressure in the system. The 'cold' pipe is about four inches long and also has an inside diameter of half an inch. The end of the pipe which butts up against the spiral piece is fitted with a washer, the central hole of which is about a quarter of an inch in diameter. Washers with larger or smaller holes can also be inserted to adjust the system.
"Three factors determine the performance of the Hilsch tube: the setting of the stopcock, the pressure at which air is admitted to the nozzle, and the size of the hole in the washer. For each value of air pressure and washer opening there is a setting of the stopcock which results in a maximum difference in the temperature of the hot and cold pipes. When the device is properly adjusted, the hot pipe will deliver air at about 100 degrees Fahrenheit and the cold pipe air at about -70 degrees (a temperature substantially below the freezing point of mercury and approaching that of 'dry ice'). When the tube is adjusted for maximum temperature on the hot side, air is delivered at about 350 degrees F.
"Despite its impressive performance, the efficiency of the Hilsch tube leaves much to be desired. This perhaps explains why no one has mathematically analyzed its operation. Indeed, there is still disagreement as to how it works.
"According to one explanation, the compressed air shoots around the spiral and forms a high-velocity vortex of air. Molecules of air at the outside of the vortex are slowed by friction with the wall of the spiral. Because these slow-moving molecules are subject to the rules of centrifugal force, they tend to fall toward the center of the vortex. The fast-moving molecules just inside the outer layer of the vortex transfer some of their energy to this layer by bombarding some of its slow-moving molecules and speeding them up. The net result of this process is the accumulation of slow-moving, low-energy molecules in the center of the whirling mass, and of high-energy, fast-moving molecules around the outside. In the thermodynamics of gases the terms 'high energy' and 'high velocity' mean 'high temperature.' So the vortex consists of a core of cold air surrounded by a rim of hot air.
"The difference between the temperature of the core and that of the rim is increased by a secondary effect which takes advantage of the fact that the temperature of a given quantity of gas at a given level of thermal energy is higher when the gas is confined in a small space than in a large one; accordingly when gas is allowed to expand, its temperature drops. In the case of the Hilsch tube the action of centrifugal force compresses the hot rim of gas into a compact mass which can escape only by flowing along the inner wall of the hot pipe in a compressed state, because its flow into the cold tube is blocked by the rim of the washer. The amount of the compression is determined by the adjustment of the stopcock at the end of the hot pipe. In contrast, the relatively cold inner core of the vortex, which is also considerably above atmospheric pressure, flows through the hole in the washer and drops to still lower temperature as it expands to atmospheric pressure obtaining inside the cold pipe.
Apparently the inefficiency of the Hilsch tube as a refrigerating device has barred its commercial application. Nonetheless amateurs who would like to have a means of attaining relatively low temperatures, and who do not have access to a supply of dry ice, may find the tube useful. It will deliver a blast of air 20 times colder than air which has been chilled by permitting it simply to expand through a Venturi tube from a high-pressure source. Thus the Hilsch tube could be used to quick-freeze tissues for microscopy, to chill photomultiplier tubes, or to operate diffusion cloud chambers. But quite apart from the tube's potential application, what could be more fun than to trap Maxwell's demon and make him explain in detail how he manages to blow hot and cold at the same time?"]]> http://typeright.social/forum/showthread.php?tid=119 Sat, 16 Sep 2023 18:36:04 +0200 JoeLag]]> http://typeright.social/forum/showthread.php?tid=119
The 8 Hz signal aligns with the perfect alpha rhythm generated when the left and right hemispheres of the brain synchronize during deep meditative states. There are various techniques for achieving this 8 Hz consciousness state, where an optimal state of bliss may be experienced. These techniques could include Transcendental Meditation, Taoist Meditation (Qi Gong), Sufi breathing exercises, and listening to the Neurophone, among others. This close synchronization of the bioplasmic signal with the Earth's Resonant Cavity (ERC) illustrates the concept of biological 'tuning' or entrainment to environmental signals.

Now, let's delve a bit deeper. In terms of scalar electromagnetics—a framework that emerges if we use Maxwell's original 20-variable equations—we might say that the bioplasmic field, the Earth's resonance, and the human consciousness could be involved in a complex multi-dimensional interaction.

Considering the idea of broken symmetry and asymmetrical re-gauging, it's conceivable that achieving such an 8 Hz resonance may "pump" the bioplasmic field from the vacuum, the Dirac sea, or whatever one wishes to call that omnipresent energy source. By tuning into this specific frequency, one could be adjusting the system's gauge symmetry, allowing the tapping of "excess" energy, much like a windmill taps into the wind.

So, in practical terms, one could experiment with generating this 8 Hz frequency using simple apparatus, perhaps employing modern-day equivalents of Tesla coils, or more sophisticated phase-conjugate mirror systems. The goal would be to emulate or boost this natural resonance and observe the effects on biological systems.]]>
The 8 Hz signal aligns with the perfect alpha rhythm generated when the left and right hemispheres of the brain synchronize during deep meditative states. There are various techniques for achieving this 8 Hz consciousness state, where an optimal state of bliss may be experienced. These techniques could include Transcendental Meditation, Taoist Meditation (Qi Gong), Sufi breathing exercises, and listening to the Neurophone, among others. This close synchronization of the bioplasmic signal with the Earth's Resonant Cavity (ERC) illustrates the concept of biological 'tuning' or entrainment to environmental signals.

Now, let's delve a bit deeper. In terms of scalar electromagnetics—a framework that emerges if we use Maxwell's original 20-variable equations—we might say that the bioplasmic field, the Earth's resonance, and the human consciousness could be involved in a complex multi-dimensional interaction.

Considering the idea of broken symmetry and asymmetrical re-gauging, it's conceivable that achieving such an 8 Hz resonance may "pump" the bioplasmic field from the vacuum, the Dirac sea, or whatever one wishes to call that omnipresent energy source. By tuning into this specific frequency, one could be adjusting the system's gauge symmetry, allowing the tapping of "excess" energy, much like a windmill taps into the wind.

So, in practical terms, one could experiment with generating this 8 Hz frequency using simple apparatus, perhaps employing modern-day equivalents of Tesla coils, or more sophisticated phase-conjugate mirror systems. The goal would be to emulate or boost this natural resonance and observe the effects on biological systems.]]>